Name: HR: Modeling Photosynthesis and Cellular Respiration Lab Introduction: Photosynthesis is the process by which green plants capture energy from sunlight and use it to make food molecules like glucose. Cellular respiration is the process used by plants and most animals, to convert the energy stored in food molecules into energy of adenosine triphosphate (ATP). ATP has high energy bonds that store energy in a form that is directly usable by plants and animals for conducting life processes such as growth, maintenance, and reproduction. Photosynthesis and cellular respiration are the fundamental processes in the flow of energy and the cycling of matter. Energy cannot be recycled because it is used. Matter, in the forms of carbon, oxygen, and hydrogen, is continually recycled. Photosynthesis: Photosynthesis is the process by which plants convert carbon dioxide into their food, by using the energy derived from the Sun. The essential materials for this process are sunlight, water, carbon dioxide, and chlorophyll. The leaves and stem of a plant have microscopic holes, known as stomata, through which the carbon dioxide enters the plant. While carbon dioxide is absorbed by leaves, water enters the plant through its roots. After being absorbed by the roots, water travels all the way through the stem to reach the leaves where photosynthesis takes place. Water is combined with carbon dioxide and used by the plant to produce oxygen and the energy-rich molecule, glucose. Oxygen is released into the atmosphere through the stomata. The chemical reaction for photosynthesis is: Cellular Respiration: Energy is defined as the ability to do work. The cells of both plants and animals require a continuous supply of energy for the performance of their life activities. Carbohydrates, especially glucose, generally provide this energy through the process of cellular respiration. The chemical reaction for cellular respiration is:
In this activity, you will (a) learn to interpret the molecular and structural formulas of water, carbon dioxide, glucose and oxygen. (b) construct molecular models to illustrate the processes of photosynthesis and cellular respiration. Materials: The Molecular Model Set for Photosynthesis and Cellular Respiration (in baggie provided) Sets include: 6 black (beads) = carbon (C) atoms 12 white (beads) = hydrogen (H) atoms 18 red (beads) = oxygen (O) atoms 24 regular (small) paper clips = single covalent bond 24 large (jumbo) paper clips = double covalent bonds You will need to get from the back lab table: 1 diagram of a plant cell 1 diagram of an animal/plant cell 1 ATP Part I Modeling Molecules: A molecule is a group of atoms held together by chemical bonds. The atoms important for photosynthesis and cellular respiration are carbon, hydrogen, and oxygen. 1. Using the molecular models, build a single molecule of water. The molecular formula for water is H2O. The structural formula for water is You need: hydrogen atoms oxygen atoms single bonds 2. Carbon dioxide, CO2, has two double covalent bonds as shown in the structural formula, O = C = O. Build a single molecule of carbon dioxide. You need: carbon atoms oxygen atoms double bonds
Part II Modeling Photosynthesis The process of photosynthesis uses light energy, carbon dioxide and water and produces glucose and oxygen. During the process of photosynthesis, light energy is converted into energy stored in the chemical bonds of glucose molecules. Chloroplasts, found in the cells of green plants and algae, are the sites for photosynthesis. 3. Place Diagram 1 (plant cell with chloroplast) in front of you on the desktop. a. What is the name of the green organelles in the cell? b. What is their function? 4. Assemble and place 6 water molecules and 6 carbon dioxide molecules on the chloroplast. a. What types of organisms have cells that contain chloroplasts? b. Without the beginning materials (reactants) for photosynthesis, plants could not survive. What is needed for the plants to survive? 5. Complete Column 1 of Table 1 by counting the number of atom (beads) models for the reactants in photosynthesis. Table 1 Column 1 Column 2 Atoms black carbon atoms white hydrogen atoms red oxygen atoms Number of Atoms in the Reactants Number of Atoms in the Products
6. In photosynthesis light energy is converted into chemical energy in a series of reactions that produce glucose and oxygen molecules. Break the bonds in the 6 carbon dioxide molecules and 6 water molecules. Using only these atoms, reassemble the atoms to make one glucose molecule. To build the glucose molecule, you need: carbon atoms, hydrogen atoms, and oxygen atoms 7. An oxygen molecule, O2, is made of two oxygen atoms bonded together with a double bond. The structural formula for the oxygen molecule is O = O. With the materials you have leftover, how many oxygen molecules can you build? Now build them! 8. Complete Column 2 of Table 1 above by counting the number of atom models for the products in photosynthesis. 9. Which product of photosynthesis remains in the green plant for use as a building material or as a source of energy? 10. Which product of photosynthesis is released as a gas into the atmosphere by green plants?
Part III Modeling Cellular Respiration: Both plant and animal cells contain organelles called mitochondria that are the principal site for cellular respiration. In cellular respiration 1 glucose molecule combines with 6 oxygen molecules to produce 6 water molecules, 6 carbon dioxide molecules, and energy stored in ATP molecules. 11. Place Diagram 2 (animal/plant cell with mitochondria) in front of you on the desktop. a. The organelle that is the principal site of cellular respiration is magnified. What is the name of this organelle? b. What types of organisms have cells with this organelle? 12. Place the glucose molecule and 6 oxygen molecules that you made during Part II, Modeling Photosynthesis, on the diagram of the mitochondria. Without the beginning materials (reactants) for cellular respiration, plants and animals cells could not convert the energy stored in food molecules into energy of ATP and they would die. What reactants are required for cellular respiration? 13. Complete Column 1 of Table 2 by counting the number of atom models for the reactants in cellular respiration. Table 2 Column 1 Column 2 Atoms black carbon atoms white hydrogen atoms red oxygen atoms Number of Atoms in the Reactants Number of Atoms in the Products 14. In cellular respiration, food molecules like glucose are converted through a series of chemical reactions into carbon dioxide, water, and chemical energy that is stored in ATP. Break the bonds in the glucose molecule and the 6 oxygen molecules. Using only these atoms, reassemble the atoms to make carbon dioxide and water molecules. a. Which reactant contains the energy released during the process of cellular respiration? b. How many carbon dioxide molecules can you make? c. How many water molecules can you make? 15. Complete Column 2 of Table 2 above by counting the number of atom models for the products in cellular respiration.
16. The energy released during cellular respiration is stored in the high-energy bonds of ATP. To model this, place ATP on the mitochondria diagram. The energy stored in ATP is used to power the plant or animal s activities such as growth, repair, digestion, excretion, and movement. To model the use of the energy stored in ATP, tear the ATP into small pieces. When the ATP is torn, the energy is used and cannot be recycled. Name two activities that you do which required energy stored in ATP. and 17. Carbon monoxide, CO, is a colorless, odorless gas that interferes with cellular respiration by significantly reducing the amount of oxygen molecules in the mitochondria. Carbon monoxide poisoning can cause brain damage and death because the process of cellular respiration is limited. When cellular respiration is limited, the organism does not make enough ATP and does not have enough for its activities. 18. Which products of cellular respiration could be released into the atmosphere and used as the reactants of photosynthesis. and 19. Is the energy obtained from sunlight during photosynthesis recycled? Explain your answer. A: Breathing: the act of breathing (inhaling and exhaling) air in order to obtain oxygen and excrete carbon dioxide. B. Cellular Respiration: the cellular metabolic process by which cells use oxygen and food to produce ATP energy that powers life activities. 20. Based on the two definitions for respiration shown in the box above, what is the relationship between breathing and cellular respiration?
Part IV Comparing Photosynthesis and Cellular Respiration: 21. When would green plants carry out photosynthesis only during the day, only at night, continuously, or never? (Support your answer with information from your textbook!--give page number) 22. When would green plants carry out cellular respiration only during the day, only at night, continuously, or never? (Support your answer with information from your textbook!--give page number) 23. Are the atoms used in photosynthesis and cellular respiration recycled? Explain how the models you made illustrate your answer. 24. During photosynthesis, light energy is converted into energy stored in molecules. 25. During cellular respiration, the energy stored in these molecules is transferred to molecules. The energy in these molecules is then used to power such as movement and chemical reactions. 26. Is the energy used in photosynthesis and cellular respiration recycled? Explain how the models illustrate your answer. 27. The number of carbon, hydrogen, and oxygen atoms on Earth remains constant. Explain how this is possible.
28. You don t carry out photosynthesis. How do you get the atoms that you need to make your body? (Hint: Look at the Food Web shown in the diagram on the right.) How do you get the energy you need for your life activities? Adapted from: Mega Molecules, LLC and Science Takeout